Automatic weighing machine



Aug. 11, 1936. RANDALL ET A 2,050,586

AUTOMATIC WEIGHING MACHINE Filed Feb. ,6, 1954 7 Sheets-Sheet l INVENTORS FPAIV/I A. RANDALL JOHN D. CANTON/- I A TTORNE Y a Aug. 11, 1936. F. A. RANDALL ET AL AUTOMATIC WEIGHING MACHINE 7 Sheets-Sheet 2 Filed Feb. 6, 1934 INVENTOR. FkA/VK A RANDALL JOHN D. CANTO/v1 BY .wLTL a'fly ATTORNEY VIIIIIIIIII/lfl I l I Aug. 1]., F A RANDALL ET AL AUTOMATIC WEIGHING MACHINE Filed Feb. 6, 1954 7 Sheets-Sheet 3 INVENTORS FRANK A RANDALL JOHN .D. CANTON/v ATTORNEY Aug. 11, 1936. F. A. RANDALL ET AL AUTOMATIC WEIGHING MACHINE 7 Sheets-Sheet 4 Filed Feb. 6, 1954 INVENTORS FRANK A RANDALL JOHN D. CANTO/VI BY ATTORNEY 1935- F. A. RANDALL ET AL AUTOMATIC WEIGHING MACHINE Filed Feb. 6, 1934 7 Sheets-Shet 6 INVENTORS FRANK A RANDALL JOHN D- CANTO/v1 By 741W ATTORNEY 1936- F. A. RANDALL ET AL 86 AUTOMATIC WEIGHING MACHINE Filed Feb. 6, 1934 7 Sheets-Sheet 7 INVENTORS FRANK A. RANDALL JOHN D. CANTON] BY .TYL L ATTORNEY Patented Aug. 11, 1936 UNITED STATES AUTOMATIC WEIGHING MACHINE Frank A. Randall and John D. Cantoni, Napa, Calif.

Application February 6, 1934, Serial No. 709,967

Claims.

Our invention relates to improvements in auto matic weighing machines. More particularly it relates to the type of weighing machine especially adapted to weigh pourable substances.

The object of our invention is to provide a fully automatic weighing machine adapted to operate with accuracy and at great speed.

Another object of our invention is the provision of a main feed for delivery of the bulk of the material onto the Weighing machine in less quantities than the exact weight desired, and an adjustable trickle feed for delivery of comparatively small amounts of material up to the exact weight.

Another object of our invention is to provide means for successive closing of the main and trickle feed, and for the discharge of weighed material from the weighing machine into a container.

Another object of our invention is to provide 'means for placing the containers in position to receive the charge of weighed material and for subsequent removal of the filled containers.

Another object of our invention is to provide an auxiliary weight which rests on the scale while the main bulk of material is being delivered onto the weighing machine from the main feed, and means for lifting said weight from the scale thereafter.

Other objects and advantages of the invention will appear as the specification proceeds, and the novel features thereof will be particularly pointed out in the appended claims.

In general terms, the apparatus of our invention consists of a main feed and a trickle feed arranged in connection therewith, into which material is fed at a substantially uniform rate. Both feeds lead to a weighing receiver attached to a standard scale in spaced relation thereto. An endless belt runs therebetween and conveys the containers which are positioned and held under said receiver by mechanism provided for that purpose.

An auxiliary weight rests on the scale while the receiver is charged up to a predetermined weight, whereupon the tilting of the scale beam closes the electric circuit and thereby instantly closes the main feed and lifts the auxiliary weight off the scale, whereupon the scale beam drops. The trickle feed delivers the amount of material necessary to make up the exact weight desired whereupon the scale beam is raised for a second time, and the electric circuit is again established, I'he mechanism controlled by said circuitsud;

cessively closes the trickle feed, discharges the weighed material from the receiver into the container, and returns the mechanism into the starting position in preparation for the next weighing operation.

Description of drawings Reference will now be made to the drawings for a more detailed description of the invention.

Figure 1 is a front elevation of the apparatus of our invention, part of the hopper being broken away in order to disclose the arrangement of parts within the same.

Figure 2 is a vertical cross-section of the apparatus taken along the line 2-2 of the Figure 1.

Figure 3 is a side elevational view of the hopper showing the arrangement of certain parts of the mechanism employed for this operation thereof.

Figure 4 is a section of the chute taken along the line 4-4 of the Figure 1.

Figure 5 is a side view of the operating mechanism of our apparatus.

Figures 6-9, inclusive, show the relation of the parts of the operating mechanism in different stages of a weighing operation.

Figure 10 is a front view of the clutch mechanism, partially broken away to disclose the arrangement of inner parts thereof.

Figure 11 is a section of the clutch taken along the line H-ll of Figure 10.

Figure 12 is a detail of the gate operating mechanism.

Figure 13 is a section of said mechanism taken along the line |3-l3 of Figure 12.

Figure 14 is a front elevational view of a container arresting mechanism.

Figure 15 is a side view of the mechanism shown in Figure 14.

Figure 16 is a detail of an electric contact, and

Figure 17 is a wiring diagram showing the circuit employed in operation of our device.

Detailed description of invention The apparatus of our invention includes a stationary hopper supported by a frame (not shown) and divided by a vertical partition 2 into a trickle feed, compartments 3 and a main feed compartment 4.

Material such as dried fruit or the like, or any other pourable substance, is delivered into the hopper l at a substantially uniform rate by .a shaker 6. Part of said material drops directly into the main feed compartment 4 while the part which is thrown farther from the shaker 6 is deflected into said feed by a deflecting partition 1 "as a bottom thereof.

covering the trickle feed 3. A comparatively small portion of material is allowed to pass into the trickle feed 3 by means of a small chute 8 leading from the shaker 6 into said feed.

As shown in Figure 4, the chute 8 comprises a side wall ID with a portion of a bottom H of the chute and a metal strip or auxiliary bottom piece [2 attached thereto, and a side wall 53 with another portion of the bottom II. The latter is afiixed to the wall of the hopper 'I and to the partition 2 while the side [9 is movable with respect thereto by means of a lever l4 and a link I6. By means of this arrangement the width of the chute 8 is adjustable and the amount of material to be delivered by the trickle feed may be conveniently and effectively regulated.

Baffle boards I! are arranged in the path of falling material inside of the feeds 3 and 4 to break the force of the falling material. An inclined bottom It restricts the discharge area of the "trickle feed 3,

At the dischargeends of the feeds 3 and 4 aroufate 'gates Z U andZi, respectively, are swingably 'i'nounted'for the purpose of instantaneously closing said feeds at predetermined periods. The gates are pivotally attached to the hopper I as at 22 and carry outwardly extending channel iron frames 23 which, in turn, have brackets 24 with "pins 25 affixed thereto. Links?! and 28 are pivotally connected to 'the pins 25, and it will be noted that the link '27 connected to the trickle feed gate 29 has an elongated slot 29 arranged therein in which th e pin 25 is adapted to slide.

The lir'ik21 'is connected to a bell crank 3e and the latter by means of a connecting rod 3! to one "end of a bell crank 32, to the other end of which the link 29 is pivotally attached. The bell crank 32 isk'eyed 'to'a shaft 33 to which a crank 35 is also keyed. The latter, by means'of a connecting rod 36, is connected tothe operating mecha- "r'iism which is to be described later.

The downward movement of the connecting rod 36 b'yir'ieans o f'the crank 35, bell crank '32 and the link 28 closes the gate 2!, the weight of the gate itself accelerating the closing. At the same time the pin 25 ofthe trickle feed gate29 rides in the slot '29 and the gate remains open, being held in that position by a trigger 38 whichen- "gages-a stop 31 afiixed to the frame 29 of said gate. At the proper moment the trigger Q8 is disengaged from the'stop 31 by a mechanism to be described later, and aspring 39 constantly closes the gate 29. The upward movement of the connecting rod 36 opens both "gates simultaneously'.

Material drops fromboth feeds into a weighinging receiver Mhaving swin g able arcuategates 42 and 43 carried thereby and adapted to serve The weighing receiver is slightly spaced from the hopper I and is supported by a frame 44 which rests on a platform 46 of a standard weighing scale 47. The latter rests on a baseGB.

Above the scale 41 and in spaced relation'thereto runs an endless belt 49 supported by a support 50. The belt 49 delivers the containers 54 under the weighing receiver, where their movement is arrested by a special mechanism to be later described in detail. The box remains under the receiver until the latter discharges its contents thereinto, and'then is allowed to continue its movement.

Asshown in Figures 1 and 16, the weighing "scale'd'l has a conventional beam 55 uponwhich connected to a source of electric energy, not shown in the drawings, and to a solenoid 69 (see Figure '17) by wires 5|, 52, and 53.

As shown inFigures 5-9 inclusive, the solenoid 69 slidably carries a plunger 61 which terminates with a link 68 the lower end of which rests on a stop 69. The latter is an integral part of an operating mechanism support 19. A spring 69a, arranged on the top of the solenoid 66, yieldably forces the plunger 61 downwardly, whereas the solenoid when being actuated pulls said plunger upwardly. The link 68 is pivotally connected to a main lever 12 which oscillates about a shaft H rotatably supported by the member 79. A link 73 operatively connects the main lever 62 and a lever 14 which rocks about a pin 15 carried by said support 19. The lever M has a cam lever 16 pivotally attached thereto, to which the connecting rod 36, previously referred to, is fastened.

Figure 5 shows a free end 18 of the cam lever and actuate's the gate'2l to closed position, as has -been previously described.

Ashort link 82 is fulcrumed on the pin 15 and carries astuh-Shaft 8'3on the other end thereof,

on which a bar 84 connecting said stub-shaft with the cam. lever .16, anda. slip arm '85, are journaled. The latter has an elongated slot '86 in the upper. end thereof in which a pin 8'! slides.

The pinBl serves as a journal to a link 88 connecting with the main lever 12 and a link 89 connecting with a clutch releasing arm 90 of a lever 9Lwhich is journaled on the shaft H.

The stub-shaft 83 is also adapted to ride in a slot 91 formed in an arm 98 of a'bell-crank 99 fulcrumed at I90, the other arm of which carries a roller 1 I112. The latter is designed to ride upon a cam I04 formed on one end of a lever I95, the other end of which pivotally carries an auxiliary weight I96. As shown in Figure 5, the weight I96 rests on a bracket I01, which is affixed to the receiver supporting frame 44.

The main lever 12, being actuated by the plunger 9? when the solenoid 66 is energized, pulls the links 13 and 98 upwardly, whereby the link l3 drops the cam lever 16 down. But the upward movement of the link 88 does not actuate the arm 90, because this movement is neutralized by the slot 86 and the pin 81 sliding freely therein as shown in Figure 6. When the cam lever 16 drops down, the bar 84 forces the stub-shaft 83 downwardly into the position shown in Fig- At the same time the stubclo'ckwise direction, causing the roller I92 to ride upon the cam I04 and thereby lift the auxiliary weight I06 off the bracket into a suspended position. The upward and downward movements 'of the main lever 12 is so rapid, that before the cam'lever 'lfidrops down this lever 12 is restored to its normal position (shown in Figure 5).

Therefore the downward movement of this lever 16 has no effect upon the clutch releasing arm 98.

The parts of the operating mechanism remain in this position until the solenoid 66 is energized a second time. Then the main lever I2 again pulls the links I3 and 88 upwardly. The movement of the link I3 swings the cam lever 15 sidewise and has no practical efiect thereon. But the link 88, having the pin 8! in the uppermost position in the slot I6 swings the slip arm 85 in counter clock-wise direction and by means of the link 89 pulls the clutch releasing arm 98 out of engagement with a clutch finger I III, as shown in Figure 8. The auxiliary weight I86 remains in suspended position because the position of the stub-shaft 83 remains the same during this operation.

The lever 9I has an upper arm II5 integral therewith to which a connecting rod H6 and a spring III are attached. The spring III urges the lever 9| into engagement with the clutch finger I I 8. The red I I6 is connected with a lever H8 (see Figure 3) which actuates the trigger 38. The latter is adjustable in relation to the lever H8 by means of a bolt I28 and is urged downwardly by a spring I I9. The rocking of the lever 9| actuates the rod H6, lever H8 and the trigger 38 thereby instantly closing the trickle feed.

The Figures 10 and 11 show in detail the clutch I24, which we employ in connection with our apparatus. It comprises a clutch drum I25, keyed to a shaft I26 and rotated in the direction shown by an arrow at a constant speed by any suitable motive power (not shown in the drawings). The drum I 25 has a series of notches I 2! fashioned on the inner side thereof. The driven clutch member 88 freely rotates about the shaft I26 and carries inside thereof a spring pressed pawl I28 having a finger I I0 integral therewith, which projects through an opening I38 outside of the member 88 and is engaged by the clutch releasing arm 98. The latter keeps the pawl I28 out of engagement with the notches I2I. But at the moment the arm 98 releases the finger II8, the pawl I28 snaps into one of the notches I 21, and the member 88 starts to rotate with the clutch drum I25.

The clutch member 88 makes one complete revolution and is disengaged from the drum I25 by the finger I I8, striking the arm 98. To prevent a backward rotation of the member 88 and engagement of the pawl I28 with one of the notches I21 while the arm 98 abuts the finger II8, a ratchet I32 carrying a roller I33 is provided. A spring I34 forces the roller I33 to ride upon the surface of the member 88 upon which a stop I35 is affixed. When the member 88 completes its rotation, the arm 98 disengages it from the clutch drum I25, and at the same time the roller I33 snaps into the position shown in Figure 11, thus arresting the backward movement of the member 88.

Besides the stud I9, the member 88 carries a cam I38 and a cam I39 aflixed to the latter, the former actuating the receiver gates 42 and 43, and the latter operating a container arresting mechanism and a scale stabilizer.

The receiver gate operating mechanism includes a long arm I 42 having a supporting leg I43 both being pivoted to frame members I44 resting on a base I 85. The arm I42 carries two rollers I41 and I48 which are so positioned as to be operated by the cams I38 and I39, respectively, and is connected to a crank I58 by means of an adjustable connecting rod I5I. As shown in Figures 12 and 13, the crank I58 is keyed to a stub-shaft I52 rotatably carried by the support I8. The stub-shaft I52 terminates with a double arm I53. In spaced relation thereto and normally in alignment with the stub-shaft I52, is a stub-shaft I5I rotatably carried by the receiver frame 44. The latter stub-shaft has a rocker arm I55 keyed thereto on the end facing the double arm I53, the other end thereof being affixed to the receiver gate 43. Integral with the rocker arm I55 are two pins I54 which are adapted to be engaged by the double arm I53 so as not to touch the latter during the weighing operation. The receiver gates 42 and 43 have teeth I58 formed at their pivotal points in mutual engagement and enabling both gates to be opened simultaneously in opposite directions.

The rotation of the clutch member 88 forces the stud I9 against the arm I 42 and swings the latter in a clock-wise direction, and by mechanism previously described opens the gates 42 and 43. At this time the roller I4I contacts the cam I38 and rides thereon, thereby keeping the gates open for the time necessary to complete the discharge of material from the receiver 48. A

spring I59 returns the arm I42 into its normal position.

The container arresting mechanism shown in Figures 15 and 16 includes a bar I6I aflixed to the leg I43 and having a stop plate I62 resting on a push rod I63. The latter is adapted to slide in a support I64 which is fixed to the side of the base 46, and by means of a crank I65 which is operatively connected to a cross shaft I66 rotatably supported by the belt support 58. Arms I6! are affixed to the shaft I66. In spaced relation thereto, dogs I68 are pivoted as at I69 and are connected to said arms by links [18. A spring II3 yieldably urges the dogs I68 upwardly, but

their motion is limited by a collar II4 affixed to the push rod I63, and a bracket II5 on the sup port I64.

When the clutch member 88 is rotated, the cam I39 actuates the roller I48 and forces the arm I42 to swing in a counter clock-wise direction, as shown in dotted lines in Figure 15, and thereby pushes the rod I63 and dogs I68, associated there with, downwardly, thus releasing the container. This movement of the arm I42 has no effect upon the receiver gates operating mechanism: it rocks the double arm I53 in a clockwise direction (looking at Figures 9 or 13) and therefore away from the pins I54.

The scale stabilizing mechanism consists of a lever I68 fulcrumed at IBI and carrying on one end a roller I82 normally resting on the cam I39. The other end of the lever I88 is connected to a stabilizer bar I33 the lower end of which is bent at a right angle as at I88 and is so positioned as to engage the frame 44 when being lifted. A .9

spring I85 lifts the bar I83 whenever the roller I82 leaves the cam I39 thereby arresting the scale 41.

Operation of the mechanism The shaker 6 delivers material at a substantially uniform rate into the main feed 4 and the trickle feed 3. The amount of material to be delivered by the latter may be regulated by changing the width of the small chute 8 by means of the lever I4. Material drops through said feeds into the weighing receiver 48 until the weight of material combined with that of the auxiliary weight I86 resting on the scale frame 44 reaches the full weight of the pack. Then the scale beam 55 is raised and the contact points 56 and- 5'! are closed. The solenoid 66 becomes energized and actuates the main lever 72, thereby closing the main feed gate 2 i, raising the auxiliary weight H35 off the frame 4 and rearranging the relation of certain parts of the mechanism in readiness to complete the weighing operation.

The raising of the auxiliary weight I56 tilts the scale beam 55 downwardly, thus disengaging the contact points 56 and 5E. The trickle feed 3, being opened, continues to deliver material into the weighing receiver ill and the scale beam 55 gradually rises up for second time. When the weight of material in the receiver exactly reaches the desired amount, the contact points close again and instantly the solenoid 66 a'ctuates the main lever 12. The upward movement of the latter sets the clutch in motion and simultaneously releases the trigger 38, thereby instantly closing the trickle feed 3.

The clutch member 36 now starts to rotate in a clockwise direction, and by means of the stud l9 swings the arm M2 and thereby opens the receiver gates 42 and 53. By cooperative action of the roller Hi1 and the cam E38 the gates are kept open for a comparatively short time, but still suflicient to completely dispose of the material stored in the receiver. Material thus discharged drops into the container which is positioned beneath the receiver Ml.

Further rotation of the clutch brings the cam E39 and the roller M8 into engagement, thereby swinging the arm H42 in counter clockwise direction. This movement of said arm operates the container arresting mechanism by forcing the push rod I63 and the dogs 68, associated therewith, downwardly. The belt 49 carries the filled container away and moves the next one into place. The length of the cam I39 is so calculated as to release the dogs I68 just behind the container, thereby immediately arresting the one following.

Rotation of the clutch member 80 brings the stud l9 and the cam lever 76 into engagement, lifts the latter into its starting position, as shown in Figure 5, and thereby simultaneously opens both feed gates and 2!. The feed gates are opened after closing of the receiver gates 42 and 43.

At the beginning of the weighing operation the roller I82 of the stabilizer lever I rests on the cam I39. Rotation of the clutch member 85 disengages said roller and cam and the spring I85 lifts the stabilizer bar E83. The latter engages the receiver frame 34 and remains engaged while the clutch rotates. A considerable amount of material accumulates in the main feed l while the latter is closed and when this mass is suddenly discharged into the weighing receiver ii the impact of the falling material may be suincient to bounce the scale beam 55 and prematurely close the contact points 55 and 57. The stabilizing mechanism eliminates the bouncing of the scale beam 55 as the spring I85 absorbs the shock. At the end of the complete revolution the stabilizer bar I83 is again disengaged from the frame 44.

The provision of the auxiliary weight H35 in conjunction with the weight stabilizing mechanism enables the main bulk of material, equal in weight to the weight of the pack minus that of the auxiliary weight, to be speedily placed upon the scale without bouncing or otherwise disturbing it so as toeffect the exactness of the weighing operation. The balance of material which must be delivered to make up the full weight is represented by a material which has been falling from the main feed at the moment the latter was closed and material which is allowed to trickle into the receiver. Strictly speaking, the closing of the trickle feed is done slightly before the predetermined weight of material in the receiver is reached, so as to allow material falling from the trickle feed to make up the exact weight. The trickle feed is made adjustable so as to enable the operator to compensate the differences in material and variations in the speed of delivery of said material. Because the contact points 57 and 55, and the trigger 38 are adjustable, the time of closing the main and trickle feed may be selected with considerable exactitude, thus assuring the accuracy of the weighing operation.

In actual practice, about 95% of the full weight of material is delivered by the main feed and about 5% by the trickle feed. Consequently, the

weighing machine works efficiently at high speeds and we have found that when handling prunes in 25 pound lots it may be successfully operated at any speed up to seven tons per hour.

If abnormal amounts of material should somehow accumulate in the main feed and then be dropped into the receiver 45, the scale beam will swing upwardly and stay in that position. The solenoid 65 will raise the main lever 12 and keep the latter in upward position as long as the former remains energized. Therefore the cam lever 16 being dropped down will swing the stub-shaft 83 downwardly and actuate the link 89 and the arm 98. The clutch mechanism will be immediately set in motion and the material will be discharged.

Although we have shown and described only one form of our invention, it should be understood that various changes or modifications may be made within the scope of the annexed claims without departing from the spirit of the invention.

What we claim and desire to secure by grant of Letters Patent is:

l. The combination of a scale having a platform, a main feed, a trickle feed, a weighing receiver resting on said platform, means for establishing an electrical circuit when a certain amount of material is discharged into the receiver, means controlled by said circuit for closing the main feed and breaking of said circuit, means for reestablishing said circuit when the weight of said material reaches the exact amount desired, and means controlled by said circuit for closing the trickle feed.

2. A weighing machine comprising a scale having a stationary frame, a platform and a beam;

a main feed; a trickle feed; a weighing receiver supported by said platform; an electric contact point affixed to the beam; a complementary contact point arranged on said stationary frame; means for closing said contact points and establishing a circuit when a certain amount of material is discharged into the receiver thereby cl0sing the main feed; means for breaking the circuit established by said points; and means for remaking the circuit to close the trickle feed when 6 in the receiver reaches a certain weight; and

kill

means for closing the trickle feed when the amount of said material reaches the exact weight desired.

4. The combination of a scale having a stationary frame, a platform and a beam with a main feed and a trickle feed associated therewith; a weighing receiver supported by the platform to catch material discharged by said feeds; a pair of contact points arranged on the beam and the stationary frame in operative relation; an auxiliary weight adapted to rest on the weighing receiver frame until the weight of material in the receiver reaches a certain amount, thereby tilting the beam and closing the contact points; means for the simultaneous closing of said main feed and the lifting of the auxiliary weight from the weighing receiver frame, thereby disengaging the contact points, means operated by the second closing of said contact points for closing the trickle feed when the weight of material in the receiver reaches the amount desired and means for discharging material from said receiver.

5. In a weighing machine, a scale, a weighing receiver attached thereto, said scale having a beam and a stationary frame; a slide affixed to the frame; a bracket slidably carried thereby; a contact point pivotally attached to the bracket, a complementary contact point carried by the beam, a circuit adapted to be closed thereby, and means within the circuit actuated upon the closing thereof for discharging material from said weighing receiver.

6. In a weighing machine, a scale, a weighing receiver carried thereby, means for delivering material into the receiver, a stabilizer bar adapted to engage the receiver for absorbing the force of the impact of material discharged by the delivering means, and means for effecting the engagement between the stabilizer bar and receiver.

'7. In a weighing machine, a scale, a weighing receiver carried thereby, means for delivering material into the receiver, a stabilizer bar adapted to engage the receiver for absorbing the force of the impact of the initial discharge of material by said delivering means, a cam for effecting the engagement between said receiver and bar and means for actuating said cam.

8. In a weighing machine, a scale having a stationary frame and a beam; a. weighing receiver supported by the scale; a main feed and a trickle feed for delivering material into the receiver; an auxiliary weight resting on said scale; a pair of contact points arranged on said frame and beam and adapted to make a circuit, a solenoid in the circuit established by the closing of said contact points, a main lever operatively connected to the solenoid; a set of levers connected to the main lever and adapted to close the main feed and raise the auxiliay weight from the scale when the circuit is closed the first time, and to successively close the trickle feed, discharge material from the receiver and open both feeds when the circuit is closed the second time.

9. In a weighing machine, a scale, a weighing receiver attached thereto, main and trickle feeds adapted to discharge material into said weighing receiver, said scale having a beam and a stationary frame, a slide affixed to the frame; a bracket slidably carried thereby; a contact point pivotally attached to the bracket, a complementary contact point carried by the beam, a circuit adapted to be closed thereby, and means within the circuit for successively closing the main feed, the trickle feed and discharging material from said weighing receiver.

10. In a weighing machine, a scale, a weighing receiver attached thereto, main and trickle feeds adapted to discharge material into said weighing receiver, an endless conveyor running under said receiver. Means for arresting movement of receptacles carried by said conveyor under said receiver, said scale having a beam and a stationary frame, a slide affixed to the frame; a bracket slidably carried thereby; a contact point pivotally attached to the bracket, a complementary contact point carried by the beam, a circuit adapted to be closed thereby, and means within the circuit actuated upon the closing thereof for successively closing the main feed and the trickle feed, discharging material from said weighing receiver, and releasing the filled receptacle held by said arresting means.

FRANK A. RANDALL. JOHN D. CANTONI. 

